Resource Recovery, Confinement, and Remediation of Environmental HazardsJohn Chadam, Al Cunningham, Richard E. Ewing, Peter Ortoleva, Mary F. Wheeler Springer Science & Business Media, 06.12.2012 - 308 Seiten This IMA Volume in Mathematics and its Applications RESOURCE RECOVERY, CONFINEMENT, AND REMEDIATION OF ENVIRONMENTAL HAZARDS contains papers presented at two successful one-week workshops: Confine ment and Remediation of Environmental Hazards held on January 15-19, 2000 and Resource Recovery, February 9-13, 2000. Both workshops were integral parts of the IMA annual program on Mathematics in Reactive Flow and Transport Phenomena, 1999-2000. We would like to thank John Chadam (University of Pittsburgh), Al Cunningham (Montana State Uni versity), Richard E. Ewing (Texas A&M University), Peter Ortoleva (In diana University), and Mary Fanett Wheeler (TICAM, The University of Texas at Austin) for their excellent work as organizers of the meetings and for editing the proceedings. We take this opportunity to thank the National Science Foundation for their support of the IMA. Series Editors Douglas N. Arnold, Director of the IMA Fadil Santosa, Deputy Director of the IMA v PREFACE Advances in resource recovery, and confinement/remediation of envi ronmental hazards requires a coordinated, interdisciplinary effort involving mathematicians, scientists and engineers. The intent of this collection of papers is to summarize recent theoretical, computational, and experimen tal advances in the theory of phenomena in porous media, with the intent to identify similarities and differences concerning applications related to both resource recovery and confinement and remediation of environmental hazards. |
Inhalt
1 | |
7 | |
multiphysics coupling for two phase flow in degenerate | 19 |
multiblock solvers and preconditioners | 41 |
Upscaling of biological processes and multiphase flow | 57 |
Foamy oil flow in porous media | 81 |
Diffusion in deformable media | 115 |
Fractures faults and the nonlinear RTM dynamics | 131 |
Diffusionlimited contamination and decontamination | 179 |
Modeling of biofilm growth in porous media | 195 |
Bioremediation | 217 |
The local discontinuous Galerkin method for advection | 231 |
Compaction and diagenesis | 247 |
Numerical simulation of freshwater salt water | 263 |
A preconditioning technique as an upscaling procedure | 283 |
List of workshop participants | 297 |
Andere Ausgaben - Alle anzeigen
Resource Recovery, Confinement, and Remediation of Environmental Hazards John M. Chadam Eingeschränkte Leseprobe - 2002 |
Resource Recovery, Confinement, and Remediation of Environmental Hazards John Chadam,Al Cunningham,Richard E Ewing Keine Leseprobe verfügbar - 2002 |
Resource Recovery, Confinement, and Remediation of Environmental Hazards John Chadam,Al Cunningham,Richard E. Ewing,Peter Ortoleva,Mary F. Wheeler Keine Leseprobe verfügbar - 2012 |
Häufige Begriffe und Wortgruppen
algorithm Applications approach approximation aquifer aquitard Basin RTM biofilm biofilm growth boundary conditions bubbles capillary pressure cell coefficient component Computational concentration contaminant convergence coupled Darcy's law deformation density diagenesis differential equations diffusion dispersed gas domain decomposition dynamic effective Environmental equilibrium Figure fine-scale finite element method fluid flow flux foamy oil fracture function Galerkin Galerkin method GMRES grid groundwater heterogeneous interface iteration L²(N linear Liu and Ball M.F. WHEELER Mathematics methane mixed finite element mortar multiblock multiphase flow multiphysics Navier-Stokes equations Newton nonlinear numerical Ortoleva overpressuring parameters Partial Differential Equations phase flow pore porosity porous media preconditioner predict problem processes profiles R.E. EWING relative permeability reservoir simulation rheology rock salt sandpack Sandstone saturation scale sediment single phase solubility solution solved sorption stress subdomain tensor theory tion transport Tuncay two-phase upscaling technique values velocity viscosity volume Water Resources